Combination computing device and game controller with touch screen input

ABSTRACT

A combination computing device and input device. The computing device provides a plurality of sides. The input device providing a structural bridge, a pair of control modules, and a touch sensitive input module attached to the back side of the input device. The pair of control modules confine the computing device on at least two opposing sides of the plurality of sides. The pair of control modules adaptively and snugly accommodate the width of the computing device, and alternatively, adaptively and snugly accommodate a width of a second computing device, the second computing device having a width greater than the width of the computing device. The structural bridge secures the pair of control modules one to the other, and, adaptively and snugly, accommodate the length of either the computing device or, the second computing device, the second computing device having a length greater than the length of the computing device.

RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent applicationSer. No. 14/840,171, filed on Aug. 31, 2015, which is acontinuation-in-part of U.S. patent application Ser. No. 14/611,804,filed on Feb. 2, 2015, now U.S. Pat. No. 9,126,119, issued on Sep. 8,2015, which is a continuation-in-part of U.S. patent application Ser.No. 13/681,153 filed on Nov. 19, 2012, now U.S. Pat. No. 8,944,912,issued on Feb. 3, 2015, which is a continuation-in-part of U.S. patentapplication Ser. No. 13/494,801 filed on Jun. 12, 2012, now U.S. Pat.No. 9,005,026, issued on Apr. 14, 2015, which in turn claims priority toU.S. Provisional Patent application Ser. No. 61/577,709 filed on Dec.20, 2011.

SUMMARY OF THE INVENTION

In a preferred embodiment, a combination includes at least, but is notlimited to, a computing device and input device. The computing deviceprovides a plurality of sides. The input device providing a structuralbridge, a pair of control modules, and a touch sensitive input moduleattached to the back side of the input device. The pair of controlmodules confine the computing device on at least two opposing sides ofthe plurality of sides of the computing device. The pair of controlmodules are configured to adaptively and snugly accommodate the width ofthe computing device, and alternatively, adaptively and snuglyaccommodate a width of a second computing device, the second computingdevice having a width greater than the width of the computing device.The structural bridge secures the pair of control modules one to theother, and adaptively and snugly accommodate the length of the computingdevice and alternatively, adaptively and snugly accommodate a length ofthe second computing device, the second computing device having a lengthgreater than the length of the computing device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front perspective view, with partial cutaway, of anembodiment an electronic game control apparatus constructed and operatedin accordance with various embodiments disclosed.

FIG. 2 shows a back plan view of the apparatus of FIG. 1.

FIG. 3 displays a right side plan view, with partial cutaway, of theapparatus of FIG. 1, constructed in accordance with various embodimentsdisclosed and claimed herein.

FIG. 4 depicts a right side plan view of the apparatus of FIG. 1,constructed in accordance with various embodiments disclosed and claimedherein.

FIG. 5 illustrates a top perspective view of an embodiment of an inputdevice of FIG. 1, constructed in accordance with various embodimentsdisclosed and claimed herein.

FIG. 6 is a block diagram of an embodiment of the apparatus of FIG. 1.

FIG. 7 is a block diagram of an alternate embodiment of the apparatus ofFIG. 1.

FIG. 8 displays a front perspective view, with partial cutaway, of acombination electronic game control and information input deviceconstructed and operated in accordance with various embodimentsdisclosed and claimed herein.

FIG. 9 depicts a back plan view of the combination of FIG. 8.

FIG. 10 illustrates a front perspective view, with partial cutaway, ofan alternate embodiment of a combination electronic game control andinformation input device constructed and operated in accordance withvarious embodiments disclosed and claimed herein.

FIG. 11 shows a top perspective view of an embodiment of an input devicewith an integrated point of sale device, the input device is constructedin accordance with various embodiments disclosed and claimed herein.

FIG. 12 displays a front perspective view, with partial cutaway, of analternate embodiment of a combination electronic game control andinformation input device, the information input device provides theintegrated point of sale device.

FIG. 13 displays a front perspective view, with partial cutaway, of analternative embodiment of a combination computing device and electronicgame control, the electronic game control includes a pair of controlmodules linked one to the other by a bridge member.

FIG. 14 shows a back plan view of the combination computing device andelectronic game control of FIG. 13.

FIG. 15 illustrates a top perspective view of the alternative embodimentof the combination computing device and electronic game control of FIG.13.

FIG. 16 shows a back plan view of an alternative combination computingdevice with a communication port secured thereon, and an input deviceattached to the communication port.

FIG. 17 shows a top plan view of the communication port of FIG. 16.

FIG. 18 shows a side view in elevation of the communication port of FIG.16.

FIG. 19 shows front and back views in elevation of a first selectedconfinement structure of the pair of confinement structures of thecommunication port of FIG. 16.

FIG. 20 shows front and back views in elevation of a second selectedconfinement structure of the pair of confinement structures of thecommunication port of FIG. 16.

FIG. 21 shows a bottom plan view of a first control module adjacent to aselected confinement structure of the pair of confinement structures ofthe communication port of FIG. 16.

FIG. 22 shows a bottom plan view of a first control module secured to aselected confinement structure of the pair of confinement structures ofthe communication port of FIG. 16.

FIG. 23 shows a side views in elevation of a first control modulesecured to a selected confinement structure of the pair of confinementstructures of the communication port of FIG. 16.

FIG. 24 shows a view in perspective of a fastening mechanism of thecommunication port of FIG. 16.

FIG. 25 shows a back plan view of the combination computing device andelectronic game control of FIG. 16 revealing, in cutout, a data storagedevice and an auxiliary power source.

FIG. 26 shows a front perspective view, with partial cutaway, of analternate embodiment of an electronic game control apparatus constructedand operated in accordance with various embodiments disclosed andclaimed herein.

FIG. 27 shows an exploded view in perspective of a first control moduleof an input device of the electronic game control apparatus of FIG. 26.

FIG. 28 shows an exploded view in perspective of a second control moduleof the input device of the electronic game control apparatus of FIG. 26.

FIG. 29 shows a back perspective view of the electronic game controlapparatus of FIG. 26.

FIG. 30 shows a front perspective view of the electronic game controlapparatus of FIG. 26, configured to accommodate computing devices ofvarying size.

FIG. 31 shows a back perspective view of the electronic game controlapparatus of FIG. 26, configured to accommodate computing devices ofvarying size.

FIG. 32 shows a front perspective view of the second control module ofthe electronic game control apparatus of FIG. 26, with a computingdevices of maximum size staged to engage the first control module.

FIG. 33 shows a front perspective view of the second control module ofthe electronic game control apparatus of FIG. 26, with the computingdevices of maximum size commencing engagement with the first controlmodule.

FIG. 34 shows a front perspective view of the second control module ofthe electronic game control apparatus of FIG. 26, with the computingdevices of maximum size fully engaged with the first control module.

FIG. 35 shows a front view of an alternative embodiment of an electronicgame control apparatus constructed and operated in accordance withvarious embodiments disclosed and claimed herein.

FIG. 36 shows a front view of an alternative embodiment of an electronicgame control apparatus, and a front perspective view of a computingdevice, which interfaces with the electronic game control apparatus toform an electronic gaming system.

FIG. 37 shows a front perspective view, with partial cutaway, of thealternative embodiment of then electronic game control apparatus of FIG.36, constructed and operated in accordance with various embodimentsdisclosed and claimed herein.

FIG. 38 shows an exploded view in perspective of a control module of theinput device of the electronic game control apparatus of FIG. 37.

FIG. 39 shows a front view of the alternative embodiment of theelectronic gaming system of FIG. 36, with a keyboard integrated into thecontrol module of FIG. 38.

FIG. 40 shows a front view of the alternative embodiment of theelectronic gaming system of FIG. 39, interacting with wirelessly with adisplay.

FIG. 41 shows a back view of the alternative embodiment of theelectronic gaming system of FIG. 37, with a touch sensitive moduleattached to a back side of the electronic gaming controller.

FIG. 42 shows a back view of an alternate alternative embodiment of theelectronic gaming system of FIG. 37, with a touch sensitive moduleattached to a back side of the electronic gaming controller.

DETAILED DESCRIPTION

The present disclosure generally relates to a combination gamecontroller and information input device directed to controllingelectronic games and entry of information to a computing device, alsoreferred to herein as video games, computer and applications games. Theapparatus preferably includes a computing device, an electronic gamecommunicating with the computing device, and an input device forcontrolling movement of a virtual object provided by the electronicgame, and entry of information into the computing device. In a preferredembodiment, the input device includes a pair of opposing side structuresadjacent opposing sides of plurality of sides of the computing device.The input device further preferably includes a plurality of inputswitches, wherein said input switches are adjacent each of the at leasttwo opposing sides of the plurality of sides of the computing device,and a bridge structure disposed between the pair of sides to form athree sided structure. The third structure mitigates inadvertent removalof the computing device from the three sided structure when thecomputing device is fully nested within the three sided structure.

Turning to the drawings, FIG. 1 provides an exemplary game controllerand information entry device (“G&D”) 100 capable of being used inaccordance with various embodiments of the present invention. Theexemplary G&D 100 has at least a computing device 102 (also referred toherein as a computing device 102), which provides a plurality of sides,such as 104, 106, 108, and 126. Each of the plurality of sides 104, 106,and 108 are disposed between an electronic display screen 110, of thecomputing device 102, and a back 112 (shown by FIG. 2) of the computingdevice 102 operates. The G&D 100 further preferably includes an inputdevice 114. The computing device 102 may take the form of a tabletcomputer, smart phone, notebook computer, or other portable computingdevice,

In a preferred embodiment, the input device 114 provides a pair of sidestructures, 116 and 118, with a bridge structure 115 disposed therebetween. One of the pair of side structures, for example 116, isadjacent to and confines the computing device 102 on a first side, suchas 104 of the plurality of sides 104, 106, 108, and 126 of the computingdevice 102. The second side structure of the pair of side structures,such as 118, is adjacent to and confines the computing device 102 on asecond side, such as 108, of the plurality of sides 104, 106, 108, and126 of the computing device 102, wherein the first and second sides,such as 104 and 108, of the plurality of sides 104, 106, 108, and 126 ofthe computing device 102 are opposing sides of the plurality of sides104, 106, 108, and 126, of the computing device 102.

In a preferred embodiment, the input device 114 further provides aplurality of removable game control modules 120 and 122, wherein theremovable game control modules 120 and 122 are adjacent each of the atleast two opposing sides 104 and 108, of the plurality of sides 104,106, 108, and 126, of the computing device 102, and a bridge structure124, disposed between the pair of side structures 116 and 118, andadjacent the third side 126, of the plurality of sides 104, 106, 108,and 126, of the computing device 102.

In a preferred embodiment, the removable game control modules 120 and122 may be removed from the input device 114, and replaced by removablekeyboard modules 164 and 166, of FIG. 8. To facilitate the exchange ofmodules, the input device preferably provides a pair of input moduleapertures 170. The removable keyboard modules collectively form a fullfunction keyboard and each provide an auxiliary electronic displayscreen (“ADS”) 168, each ADS 168 having at least the functionality ofthe electronic display screen 110.

In an alternate embodiment, shown by FIG. 10, the removable keyboardmodules 164 and 166 are a pair of touch responsive electronic displayscreens 172 and 174, each of the touch responsive electronic displayscreens having at least the functionality of the electronic displayscreen 110, include the functionality of a mouse pad portions 176 and178, and selectively presents keys of a keyboard 180 and 182 forinformation entry. Preferably, the keys are virtual keys that respond toa touch by a user.

Returning to FIG. 1, preferably, the bridge structure 124 in combinationwith the pair of side structures 116 and 118 form a three sidedstructure 128 (of FIG. 5) (also referred to herein as a u-shapedstructure 128 of the input device 114), in which the computing device102 nests, such that the computing device 102 is confined by theu-shaped structure 128, and the u-shaped structure 128 mitigatesinadvertent removal of the computing device 102 from the u-shapedstructure 128 when the computing device 102 is fully nested within thethree sided structure 128.

The G&D 100 of FIG. 1, further preferably includes a video game 130.Preferably, the video game 130 provides a virtual object 132 displayedby the electronic display screen 110, the virtual object 132 isresponsive to input from the input device 114. An example of a responseof the virtual object 132 would be movement of the virtual object 132,or the loading of an alternate computer game, based on a predeterminedsignal provided by the input device 114, or an appearance of acharacter. It is noted that FIG. 1 displays the housings of theplurality of switches, whereas at least some of the plurality ofswitches are shown in the partial cutaway of FIG. 3.

FIG. 2 depicts and reveals the back 112 of the computing device 102.Further shown by FIG. 2, is the input device 114, which provides a pairof trigger switches 136 and 138, supported by their corresponding sidestructures 116 and 118 respectively.

FIG. 3 shows that a predetermined number of the plurality of switches140, collaborate with each other to form an input apparatus 142, theinput apparatus 142 controls display of virtual objects displayed on theelectronic display screen 110 of the computing device 102. Preferably,the input apparatus 142 is a joystick 142. FIG. 3 further shows that theinput device 114 provides a plurality of buttons 144 and 119 of theremovable game control modules 120, which activate correspondingswitches 145 and 121. The main function of the trigger 138, the joystick142, and the buttons 144 and 119 of the removable game control modules120 is to govern the movement/actions of a playable body/object orotherwise influence events in a video game 130 (of FIG. 1) or analternate computer game.

FIG. 4 shows the G&D 100, further includes a second joystick 146, and asecond button 148, which are provided on the side structure 116,adjacent the trigger 136. While FIG. 5 shows the central processing unit(CPU) 150, of the input device 114.

FIG. 6 shows the input device 114 includes the CPU 150, interacting withthe plurality of switches 152, which preferably include at leastswitches 119 of the removable game control modules 120 (of FIG. 1),switches 117 of the removable game control modules 122 (of FIG. 1), 136,138, 142, 144, 146, and 148 (of FIGS. 2 and 3). FIG. 6 further shows theinput device 114 includes a communications protocol 154 providing thecommunication link between the computing device 102, and the inputdevice 114. In a preferred embodiment, a Universal Serial Bus (USB)communications protocol is utilized. However, as those skilled in theart will recognize, the communications protocol 154 is not limited to aUSB protocol.

FIG. 6 further shows that the computing device 102 preferably includesat least a CPU 156, interacting with the electronic display screen 110,the video game 130, a device driver 158, which facilitates theinteraction between the computing device 102 and the input device 114,and a communications protocol 160 providing the communication linkbetween the computing device 102, and the input device 114. In apreferred embodiment, a Universal Serial Bus (USB) communicationsprotocol is utilized. However, as those skilled in the art willrecognize, the communications protocol 160 is not limited to a USBprotocol.

FIG. 7 shows an alternative embodiment of an exemplary game controller162, in which the device driver 158 and the video game 130 are locatedin the input device 114.

FIG. 8 shows in a preferred embodiment, the G&D 100 includes a firstcamera 184, on a first side of the computing device 102, a second camera186, on the back side of the computing device 102 (shown by FIG. 9), athird camera 188 on a first side of the input device 114, and a fourthcamera 190 on the back side of the input device 114 (shown by FIG. 9).

In a preferred embodiment, each of the four cameras may selectivelyfunction independently, or may be used in conjunction with one another,and each of the four cameras 184, 186, 188, and 190 are fully functionalin capturing still and video images. Additionally, and preferably, thefirst and second cameras 184 and 186, are fully operative, even when thecomputing device 102 is detached from the input device 114, while thethird and fourth cameras 188 and 190 are fully functional, even when theinput device 114 is detached from the computing device 102.

In a preferred embodiment, when the computing device 102 is nested inthe input device 114, the first and second cameras, 184 and 186, areresponsive, either independently or simultaneously, to input from eitherthe computing device 102, or the input device 114, depending on whichdevice is selected for control of the first and second cameras, 184 and186. Further, in the preferred embodiment, each the computing device 102and the input device 114, are configured with a Bluetooth protocol stackcommunication feature, which permits the user to operate the first andsecond cameras, 184 and 186, of the computing device 102 with the inputdevice 114, even when the computing device 102 is detached from theinput device 114. Likewise, when the computing device 102 and the inputdevice 114 are configured with a Bluetooth protocol stack communicationfeature, the user may operate the third and fourth cameras, 188 and 190,of the input device 114, using the computing device 102. In other words,in the preferred embodiment, each of the four cameras 184, 186, 188, and190, may be selectively operated, individually or collectively, whetheror not the computing device 102 is nested within the input device 114.

FIG. 9 shows that in a preferred embodiment, the input device 114,includes an auxiliary power source 192, and an auxiliary data storagedevice 194, which preferably includes a cache portion 196. Preferably,the auxiliary power source 192, is a lithium ion battery, which providespower to the input device 114, and the computing device 102, when thepower source of the computing device 102 is depilated; and the auxiliarydata storage device 194 is a solid state hard drive.

In the preferred embodiment, the cache 196 is sized to buffersynchronized input from each of the cameras 184, 186, 188, and 190, suchthat the auxiliary data storage device 194 may store and retrieveimages, still or video, for display seamlessly, including a simultaneousoutput of video images recorded by each of the cameras 184, 186, 188,and 190.

In a non-limiting exemplary application of utilizing the cameras 184,186, 188, and 190, the first camera 184 could be trained on aninformation presenter, while the second camera 186 is trained on aportion of an audience attending the presentation. The third camera 188,could be trained on a screen used by the presenter for presenting theirinformation to the audience, while the fourth camera is trained on analternate portion of the audience. By simultaneously replaying therecorded presentation, a response of the audience to the information,and sequence of information being presented, may be analyzed forfostering improvements to the presentation.

FIG. 11 shows an alternative embodiment of a video game controller 200,which provides an integrated transaction card input feature 202.Preferably, the integrated transaction card input feature 202, includesa transaction card slot 204, and a transaction card reader 206. In apreferred embodiment, the transaction card reader 206, is a magneticstrip reader, but as those skilled in the art will recognize, thetransaction card reader can be, in the alternate: is an opticalcharacter recognition reader; a barcode reader; an object recognitionreader, or a pattern recognition reader.

FIG. 12 shows that in a preferred embodiment, a combination computingdevice and electronic game controller with an integrated point of saledevice 210 preferably includes a computing device 212, having aplurality of sides 214, each of the plurality of sides 214, are disposedbetween an electronic display screen 216, of the computing device and aback 218 of the computing device, and an input device 220, in electroniccommunication with the computing device 212. The input device 220preferably provides side structures 222, adjacent to and confining thecomputing device on at least two opposing sides of the plurality ofsides 214 of the computing device 212. The input device 220, furtherpreferably provides input module apertures 224, each input moduleaperture 224, selectively accepts either a game control module, such as102 and 122 of FIG. 1, or a removable keyboard module, such as 226 and228. Preferably, the input module apertures 224 are adjacent each of theat least two opposing sides of the plurality of sides 214 of thecomputing device 212.

FIG. 12 further shows that in a preferred embodiment, the combinationcomputing device and electronic game controller with an integrated pointof sale device 210 preferably includes a camera 230, communicating witheach the input device 220, and the computing device 212. The camera 230,selectively captures either still or video images, and that the inputdevice 220, further provides an integrated transaction card inputfeature 232, which interacts with a transaction card 234, and thatpreferably, the input device is an electronic game controller 220.Preferably, the camera 230 is a first camera, having a lens facing theuser while the user is facing the electronic display screen 216, andincludes at least a second camera, such as 186 or 190 (of FIG. 9),having a lens facing in a direction opposite that of the first camera184.

FIG. 12 additionally shows an application 236, displayed on theelectronic display screen 216, of the computing device 212. Preferably,the application 236, displayed on the electronic display screen 216 ofthe computing device 212, is a point of sale transactional computerapplication, which interacts with the electronic game controller 220 andthe computing device 212.

FIG. 13 shows an alternative embodiment of a combination computingdevice and electronic game control 240 (also referred to herein as adevice 240). The computing device 242, preferably provides a pluralityof sides 244, each of the plurality of sides are disposed between anelectronic display screen 246, of the computing device 242, and a back248 of the computing device 242.

Preferably, the electronic game controller 250 (also referred to hereinas input device 250), is in electronic communication with the computingdevice 242. Preferably, the input device 250, provides a pair of controlmodules 252. The pair of control modules 252, are adjacent to andconfining the computing device 242, on at least two opposing sides ofthe plurality of sides 244, of the computing device 242. The pair ofcontrol modules 252, preferably provide input module apertures 254, eachinput module aperture 254, secures an instructional input device 256.Preferably, the input module apertures 254, are adjacent each of the atleast two opposing sides of the plurality of sides 244, of the computingdevice 242.

FIG. 14 shows the back 248, of the computing device 242, and thecomputing device 242, partially positioned within the input device 250.FIG. 14 further shows a structural bridge 258, securing the pair ofcontrol modules 252, one to the other, and communicating with the back248, of the computing device 242, at a mid-region 260, of the back 248,of the computing device 242.

FIG. 14 further shows that the pair of control modules 252, provide aconfinement boss 262, and the confinement boss 262 provides a fasteningdetent 264. The fastening detent 264, interacts with a retention member266, to secure the structural bridge 258, to the pair of control modules252. In a preferred embodiment, the retention member 266, is responsiveto a catch 268, which preferably is a spring activated catch 268, andthe retention member 268 is preferably a spring loaded retention member268. Still further, FIG. 14, shows that in a preferred embodiment, thestructural bridge 258, provides a communication link 270, which passingsignals between the pair of control modules 252.

Continuing with FIG. 14, in a preferred embodiment, the communicationlink 270, provides a communication module 272, and in the alternative,provides a signal pathway 274, for use in passing signals between thepair of control modules 252. In a preferred embodiment, thecommunication module 272 is a wireless communication module 272, whichoperates in a frequency range of 2.4 GHz. In an alternate preferredembodiment, the wireless communication module 272 is a personal areanetwork. As those skilled in the art, a personal area network (PAN) is acomputer network used for communication among computerized devices,including telephones and personal digital assistants. PANs can be usedfor communication among the personal devices themselves (intrapersonalcommunication), or for connecting to a higher level network and theInternet (an uplink). A wireless personal area network (WPAN) is a PANcarried over wireless network technologies such as IrDA, Bluetooth,Wireless USB, Z-Wave, ZigBee, or even Body Area Network. The reach of aWPAN varies from a few centimeters to a few meters. A PAN may also becarried over wired computer buses such as USB and FireWire.

In an embodiment that utilizes the signal pathway 274, as thecommunication link, the signal pathway 274 may be in the form of ametallic conductor, a fiber optic conductor, a conductive polymer, orthe conductive layer of a flex circuit. The skilled artisan will furtherappreciate that the structural bridge 258 (of FIG. 14), or 276 (of FIG.15) may be either formed from a ridged material, such as a ridgedpolymer, or from a flexible material, such as a flexible polymer. In apreferred embodiment, when a flexible material is selected, and thesignal pathway 274 is a wired pathway, the signal pathway 274 may becoupled externally to the structural bridge 276, as shown by FIG. 15.

FIG. 15 further shows that in a preferred embodiment, the instructionalinput device 256, may be an electronic game control module 278 (whichmay be either removable, or fixed), or a keyboard module 280 (of FIG.13, which may be either removable, or fixed).

FIG. 16 shows a back plan view of an alternative combination 300, whichpreferably includes, but is not limited to, a computing device 302 thatprovides a plurality of sides 304, each of the plurality of sides aredisposed between an electronic display screen 306 (of FIG. 13) of thecomputing device and a back 308 of the computing device 302. Preferably,the alternative combination 300 further includes a communication port310, interacting with the computing device 302. In a preferredembodiment, the communication port 310 provides a communication link 312(which for purposes of illustration is shown as a wired connection 314,but will be understood to be a wireless connection in an alternativeembodiment). Preferably, the communication port 310, further provides apair of confinement structures 316, the pair of confinement structures316, which are preferably adjacent to and confining the computing device302 on at least two opposing sides of the plurality of sides 304 of thecomputing device 302.

The alternative combination 300, further preferably includes an inputdevice 318 (also referred to herein as input device 114), attached toand in electronic communication with the communication port 310. Theinput device 318 providing a pair of control modules 252, the pair ofcontrol modules 252 providing input module apertures 224 (of FIG. 12),each input module aperture 224 secures an instructional input device 356(of FIG. 23), or such as 120 of FIG. 11, or 256 of FIG. 13. Preferably,the input module apertures 224, are adjacent each of the at least twoopposing sides of the plurality of sides 304, of the computing device302, and wherein the input device 356, or such as 120 of FIG. 11, or 256of FIG. 13, is a separate and distinct structure from the communicationport 310, forming no structural portion of the communication port 310.

FIG. 16 further shows that in a preferred embodiment, the communicationport 310, further includes a fastening mechanism 320 (also referred toherein as retention mechanism 320). In one embodiment, a soft drawlatch, such as that provided by Southco, of 210 N. Brinton Lake RoadConcordville, Pa. 19331, have been shown to be a useful retentionmechanism 320.

FIG. 17 shows a top view of the communication port 310 that preferablyincludes a structural bridge 322, securing the pair of confinementstructures 316, one to the other. The structural bridge 322 ispreferably secured to a select confinement structure of the pair ofconfinement structures 316 by way of a solid connection 324, and toremaining confinement structure of the pair of confinement structures316 by way of a slip fit 326. The retention mechanism 320, is preferablysecurely fastened to to a conduit 328, of the structural bridge 322, byway of a anchor member 330, the anchor member 330 is preferablypositioned in a location adjacent the slip fit 326, and by way of anattachment member 332 (shown in FIG. 18), securely attached to theremaining confinement structure of the pair of confinement structures316. The attachment member 332, is preferably positioned in a locationadjacent the slip fit 326. Operation of the retention mechanism 320,facilitates an expand and contract of the distance between the pair ofconfinement structures 316. The expansion and contraction of thedistance between the pair of confinement structures 316, facilitatesplacement of the computing device 302 between the pair of confinementstructures 316, the application of sufficient compressive load beingplaced on the computing device 302 to securely hold the computing devicebetween the pair of confinement structures 316, and an ability to removethe compressive load and allow removal of the computing device from thecommunication port 310.

FIG. 17 further shows that each of the pair of confinement structures316, provide a pair of controller docking pins 334, while FIG. 18 showsthat each of the pair of confinement structures 316 further provide acomputing device cradle 336, and that a select confinement structure ofthe pair of confinement structures 316 provides a computing deviceinterface feature 338. The interface feature 338, facilitates at least,but not limited to, the provision of power to the computing device 302.

FIG. 19 shows a front view 340, of a first selected confinementstructure of the pair of confinement structures 316, which reveals aplurality of signal input lands 342 for use in receiving signals fromthe input device 318, of FIG. 16, and the pair of controller dockingpins 334.

Further shown by FIG. 19, is a back view 344 of the first selectedconfinement structure of the pair of confinement structures 316, whichreveals computing device interface feature 338, the computing devicecradle 336, and the slip fit 326.

FIG. 20 shows a front view 346, of a second selected confinementstructure of the pair of confinement structures 316, which reveals aplurality of signal input lands 342 for use in receiving signals fromthe input device 318, of FIG. 16, and the pair of controller dockingpins 334.

Further shown by FIG. 20, is a back view 348 of the second selectedconfinement structure of the pair of confinement structures 316, whichreveals, the computing device cradle 336, and the solid connection 324.

FIG. 21 reveals, for purposes of disclosure and for consistency of viewswith remaining disclosed figures of an embodiment, a bottom right handplan view of the input device 318 adjacent the second selectedconfinement structure of the pair of confinement structures 316, of thecommunication port 310. Preferably, the control module 252, provides anattachment structure 350, cooperating with the controller docking pins334, of the communication port 310. The attachment structure 350,secures the input device 318, to the communication port 310. In apreferred embodiment, the attachment structure 350, provides a slidinglocking toggle 352, and a fixed locking toggle 354. In the embodimentpresented, the sliding locking toggles, 352, interact with thecontroller docking pins 334, to securely (but removable) fasten theinput device 318 to the communication port 310. In a preferredembodiment, the sliding locking toggle 352, is selectively adjustablefrom an open position, shown in dashed lines, and a closed, or lockedposition, as shown in solid lines.

FIG. 22 shows the input device 318, securely fastened to thecommunication port 310, by way of the attachment structure 350, whileFIG. 23 shows the right control module 252, of the input device 318,with its accompanying attachment structure 350 in a locked position, andthe special relationship of the control module 252, relative to theconfinement structure 316. FIG. 23 further shows an instructional inputdevice 356, such as 120 of FIG. 11, or 256 of FIG. 13, which in apreferred embodiment is a removable instructional input device 356.

FIG. 24 provides a more insightful presentation of a latch portion 358,of the fastening mechanism 320, relative to the attachment member 332,of the fastening mechanism 320.

FIG. 25 shows that in a preferred embodiment, the input device 318,includes an auxiliary power source 360, and an auxiliary data storagedevice 362, which preferably includes a cache portion 364.

FIG. 26 shows a front perspective view, with partial cutaway, of analternate embodiment an electronic game control apparatus 400 (alsoreferred to herein as an input device 400), constructed and operated inaccordance with various embodiments disclosed and claimed herein. Theinput device 400 includes, but is not limited to, a first control module402, and a second control module 404. The control modules (402, 404) areadjacent to and confine a computing device 406 (of FIG. 30) on at leasttwo opposing sides 408 and 410 (each of FIG. 30), of the plurality ofsides of the computing device 406.

In a preferred embodiment, the computing device 406, has a length 412,greater than its width 414, as shown by FIG. 30. The pair of controlmodules (408, 410) are preferably configured such that the pair ofcontrol modules (408, 410) adaptively and snugly accommodate the width414, of the computing device 406. Alternatively the pair of controlmodules (408,410) adaptively and snugly accommodate a width 416 (of FIG.30), of a second computing device 418 (of FIG. 30). Preferably, thewidth 416, of the second computing device 418, is greater than the width414, of the computing device 406, and preferably, the second computingdevice 418, has a length 420 (of FIG. 30) greater than the width 414, ofthe second computing device 418.

Preferably, the input device further provides a structural bridge 422,which secures the pair of control modules (402, 404), one to the other.The structural bridge 422 is preferably configured such that thestructural bridge 422, adaptively and snugly accommodate the length 412,of the computing device 406. Alternatively, the structural bridge 422,adaptively and snugly accommodate the length 420, of the secondcomputing device 418. Preferably, the length 420 of the second computingdevice 418, is greater than the length 412, of the computing device 406.Without limitations imposed upon the accompanying claims, in a preferredembodiment, the structural bridge 422, is formed from a flexiblematerial, such as a flexible polymer, or alternatively, from asemi-ridge material, such as a semi-ridged polymer, fiber glass,metallic sheet material, carbon fiber, or other materials known toartisans skilled in the art.

FIG. 27 shows an exploded view in perspective of the first controlmodule 402, of the input device 400, of FIG. 26. The first controlmodule 402, of the pair of control modules (402, 404), preferablyincludes at least, but is not limited to, a retention mechanism 424,communicating with the structural bridge 422 (of FIG. 26), wherein theretention mechanism 424, secures the structural bridge 422 such that thestructural bridge 422, adaptively accommodates the length of thecomputing device 406. Alternatively, the structural bridge 422,adaptively accommodates the length 420, of the second computing device418. In a preferred embodiment, the length 420 of the second computingdevice 418, is greater than the length 412, of the computing device 406.

FIG. 27 further shows that the first control module 402, provides a base426, which provides an adjustment feature 428. And preferably, theretention mechanism includes at least, but is not limited to, a boss430, communicating with the structural bridge 422, and an adjustmentstructure 432, interacting with the boss 430, by way of the adjustmentfeature 428. In a preferred embodiment, the base 426 is disposed betweenthe adjustment structure 432, and the boss 424.

The first control module 402, preferably provides a restraint 434,cooperating with the boss 430. As shown by FIG. 29, the restraint 434,retains the structural bridge 422, in a first position 436, relative tothe base 426, when the adjustment structure 432, is activated in a firstdirection 438, relative to the base 426. When positioned in the firstposition 436, the structural bridge 422, accommodates the secondcomputing device 418, as more clearly shown in FIG. 30.

The adjustment structure 432, further retains the structural bridge 422,in a second position 440, relative to the base 426, when the adjustmentstructure 436, is activated in a second direction 442, relative to thebase 426. When positioned in the second position 440, the structuralbridge 422, accommodates the first computing device 406, as shown byFIG. 30. To accommodate the first position 436, and the second position440, preferably the boss 432, provides a constraint feature 444, whichcooperates with the base 426. The constraint feature 444, maintains thestructural bridge 422, in the first position 436, relative to the base426, following an activation of the adjustment structure 432, in thefirst direction 438. The constraint feature 444, further maintains thestructural bridge 422, in the second position 440, relative to the base426, following an activation of the adjustment structure 432, in thesecond direction 442. The second direction 442, is a direction oppositethat of the first direction 438, and in the preferred embodiment, therestraint 434, is a spring member.

FIG. 28 shows an exploded view in perspective of the second controlmodule 404, of the input device 400, of FIG. 26. The second controlmodule 404, includes at least but is not limited to, a tensioningmechanism 446, communicating with the structural bridge 422, by way of afastening mechanism 448 (also referred to herein as an attachment stay448), of the tensioning mechanism 446 secured to the structural bridge422, as shown by FIG. 26.

The tensioning mechanism 446, secures the structural bridge 422, to abottom cover 450, of the second control module 404, such that thestructural bridge 422, cooperating with the tensioning mechanism 446,snugly accommodates the length 412 (of FIG. 30), of the computing device406 (of FIG. 30). Alternatively, the tensioning mechanism 446, securesthe structural bridge 422 to the bottom cover 450, of the second controlmodule 404, such that the structural bridge 422, cooperating with thetensioning mechanism 446, snugly accommodates the length 420 (of FIG.30) of the second computing device 418 (of FIG. 30). In a preferredembodiment, the length 420, of the second computing device 418, isgreater than the length 412, of the computing device 406.

In a preferred embodiment, the bottom cover 450, provides a positionguide 452, and the tensioning mechanism 446, includes at least, but notlimited to, the attachment boss 452, communicating with the structuralbridge 422, an attachment support 456, cooperating with the attachmentboss 452. Preferably, the attachment support 456, in cooperation withthe attachment boss 452, confines the structural bridge 422 vertically,but permits lateral movement of the structural bridge 422 relative tothe bottom cover 450.

Preferably, the structural bridge 422, is disposed between the bottomcover 450, and a top cover 458, which cooperates with the bottom cover450, to facilitate lateral movement of a portion of the structuralbridge 422, from its position associated with the first position 432 (ofFIG. 29) of the the adjustment structure 432 (of FIG. 29), to itsposition associated with the second position 440 (of FIG. 29) of theadjustment structure 432, while a biasing structure 460, communicatingwith the attachment stay 448 (of FIG. 26), provides variable tensionbetween the structural bridge 422, and the second control module 404,thereby accommodating a predetermined amount of lateral movement of thestructural bridge 422, relative to the bottom cover 450, as shown byFIG. 26.

In a preferred embodiment, the attachment stay 448, includes at least,but not limited to, a guide aperture 462, which is preferably slotted,interacting with a position guide 454, of the attachment boss 452. Theinteraction of the guide aperture 462, with the position guide 454,limits the extent of lateral alignment between the structural bridge422, and the second control module 404. As further shown by FIG. 28, ina preferred embodiment, the attachment support 456, further supports aplurality of control switches 464, interacting with a circuit structure466, which preferably is a flex circuit 466, the biasing structure 460,is a coiled spring 460.

Preferably, each of the pair of control modules, 402 of FIG. 27 and 404of FIG. 28, include at least, but not limited to, a sizing mechanism468, communicating with a computing device 406 (of FIG. 30), else asecond computing device 418 (of FIG. 30). In a preferred embodiment, thesizing mechanism 468 is configured such that the sizing mechanism 468adaptively accommodate the width 414, of the computing device 406.Alternatively the sizing mechanism 468, adaptively accommodate the width416, of the second computing device 418. In a preferred embodiment, thewidth 416, of the second computing device 418, is greater than the width414, of the computing device 406.

As shown by FIG. 27, the control module 402, includes the base 426,which provides a sizing toggle confinement structure 470, and a slidesupport confinement structure 472. Preferably, the sizing mechanism 468includes at least, but is not limited to, a sizing toggle 474,communicating with the sizing toggle confinement structure 472, a sizingtoggle restraint 476, interacting with the sizing toggle confinementstructure 472, the sizing restraint 476, promotes rotation of the sizingtoggle 474, relative to the base 426.

In a preferred embodiment, the sizing mechanism further includes atorsional force structure 478, cooperating with the base 426, and actingon the sizing toggle 474. The torsional force structure 478,facilitating the sizing toggle 474, in a first position under a firsttorsional force. When in the first position, the sizing toggles 474,extend vertically from the base 450, and the control module 402 isconfigured to accommodate the width 410, of the computing device 406.Alternatively, the torsional force structure 478, facilitating thesizing toggle 474, in a second position under a second torsional force.When in the second position, the sizing toggles 474, lies nested in thesizing toggle confinement structure 472, and horizontal the base 450,and the control module 402 is configured to accommodate the width 416,of the second computing device 418. Preferably, the second torsionalforce is greater than the first torsional force, and the width 416, ofthe second computing device 418, is greater than the width 414, of thecomputing device 406.

In a preferred embodiment, the control module 402, further provides acomputing device slide pad 480, nested in the slide support confinementstructure 472. The computing device slide pad 480, is configured todeliver minimal sliding friction between the computing device 406, orthe second computing device 418, and the control module 402, wheninserting either computing device (406, 418) into the control module402. Likewise, the sizing toggle 474, is configured to deliver minimalsliding friction between the computing device 406, or the secondcomputing device 418, and the control module 402, when inserting eithercomputing device (406, 418) into the control module 402.

Preferably, the torsional force structure 478, is a coiled spring, andthe sizing toggle confinement structure 470, provides a friction surface482, which mitigates an inadvertent movement of the sizing toggle 474,from the first position to the second position when the computing device406, is constrained by the input device 400.

Turning to FIG. 31, shown therein are FIGS. 31a and 31b . As can be seenby FIG. 31a , the control modules (402, 404), and the structural bridge422, of input device 400, are positioned, relative to one another, toaccommodate the computing device 406 (of FIG. 30). While as can be seenby FIG. 31b , the control modules (402, 404), and the structural bridge422, of input device 400, are positioned, relative to one another, toaccommodate the second computing device 418, of FIG. 30.

FIGS. 32, 33, and 34 collectively illustrate a preferred procedure tojoin the second computing device 418, with the control module 404. Thefirst step in the procedure is to align the second computing device 418,with the control module 404, such that the corner of the secondcomputing device 418, is adjacent the sizing toggle 474 as shown by FIG.32. The next step in the procedure is to advance the second computingdevice 418, into contact with the sizing toggle 474, and continue toadvance the second computing device 418, into the control module 404,which causes the sizing toggle 474, to rotate into the sizing toggleconfinement structure 470, thereby permitting the second computingdevice 418, to be adaptively and snuggly accommodated by the controlmodule 404.

FIG. 35 shows a front view of an alternate embodiment of an electronicgame control apparatus 500 (also referred to herein as an input device500), constructed and operated in accordance with various embodimentsdisclosed and claimed herein. The input device 500 includes, but is notlimited to, a first control module 502, and a second control module 504.The control modules (502, 504) are adjacent to and confine a computingdevice 506 (of FIG. 36) on at least two opposing sides 508 and 510 (eachof FIG. 36), of the plurality of sides of the computing device 506.Collectively, and when joined together, by way of a structural bridge522, the input device 500, and the computing device 506, form anelectronic gaming system 511, as shown in FIG. 36.

In a preferred embodiment, the control module 504, incorporates theeternal mechanisms and features of the control module 404, of FIGS. 26and 28, including the tensioning mechanism 446, but absent the sizingmechanism 468. While the control module 502, incorporates the eternalmechanisms and features of the control module 402, of FIGS. 26 and 27,but absent the adjustment feature 428, and the sizing mechanism 468.Accordingly, the input device 500 can accommodate computing devices ofvarying length and width by incorporating the tensioning mechanism 446,into control module 504, to accommodate a length 513, of the computingdevice 560, and configuring the control modules (502, 504) to allow thesides (508, 510) of the computing device 506, to protrude, or extendbeyond the confines of a length 515, of the control modules (502, 504),in a vertical direction along a width 517, of the computing device 506.

In a preferred embodiment, as shown by FIG. 35, the structural bridge522, secures the pair of control modules (502, 504) one to the other.Preferably, the structural bridge 522, is configured such that thestructural bridge 522, adaptively and snugly accommodate the length 513,of the computing device 506, as shown in FIG. 36.

In a preferred embodiment, as shown by FIG. 37, the control module 504,includes at least, but is not limited to, a tensioning mechanism 546,communicating with the structural bridge 522. Preferably, the tensioningmechanism 546, secures the structural bridge 522, such that thestructural bridge snugly accommodate the length 513 (of FIG. 36), of thecomputing device 506 (of FIG. 36).

In a preferred embodiment, as shown by FIG. 35, a communication link519, is provided by the input device 500, which facilitatingcommunication between the pair of control modules (502, 504) and thecomputing device 506 (of FIG. 36), and, as shown by FIG. 35, thestructural bridge 522, masks a mid-portion of the back of the computingdevice.

Continuing with FIG. 35, in a preferred embodiment, the communicationlink 519, provides a communication module 521, and in the alternative,provides a signal pathway 523, for use in passing signals between thepair of control modules (502, 504). In a preferred embodiment, thecommunication module 521, is a wireless communication module 521, whichoperates in a frequency range of 2.4 GHz. In an alternate preferredembodiment, the wireless communication module 521, is a personal areanetwork. As those skilled in the art, a personal area network (PAN) is acomputer network used for communication among computerized devices,including telephones and personal digital assistants. PANs can be usedfor communication among the personal devices themselves (intrapersonalcommunication), or for connecting to a higher level network and theInternet (an uplink). A wireless personal area network (WPAN) is a PANcarried over wireless network technologies such as IrDA, Bluetooth,Wireless USB, Z-Wave, ZigBee, or even Body Area Network. The reach of aWPAN varies from a few centimeters to a few meters. A PAN may also becarried over wired computer buses such as USB and FireWire.

In an embodiment that utilizes the signal pathway 523, as thecommunication link 519, the signal pathway 523, may be in the form of ametallic conductor, a fiber optic conductor, a conductive polymer, orthe conductive layer of a flex circuit. The skilled artisan will furtherappreciate that the structural bridge 522, may be either formed from aridged material, such as a ridged polymer, or from a flexible material,such as a flexible polymer.

FIG. 38 shows an exploded view in perspective of the control module 504,of the input device 500, of FIG. 35. The control module 504, includes atleast but is not limited to, a tensioning mechanism 546, communicatingwith the structural bridge 522, by way of a fastening mechanism 548(also referred to herein as an attachment stay 548), of the tensioningmechanism 546 secured to the structural bridge 522, as shown by FIG. 37.

The tensioning mechanism 546, secures the structural bridge 522, to abottom cover 550, of the control module 504, such that the structuralbridge 522, cooperating with the tensioning mechanism 546, snuglyaccommodates the length 513 (of FIG. 36), of the computing device 506(of FIG. 36).

In a preferred embodiment, the bottom cover 550, provides an attachmentboss 552, supporting a position guide 554, and the tensioning mechanism546, includes at least, but not limited to, the attachment boss 552,communicating with the structural bridge 522, an attachment support 556,cooperating with the attachment boss 552. Preferably, the attachmentsupport 556, in cooperation with the attachment boss 552, confines thestructural bridge 522 vertically, but permits lateral movement of thestructural bridge 522, relative to the bottom cover 550.

Preferably, the structural bridge 522, is disposed between the bottomcover 550, and a top cover 558, which cooperates with the bottom cover450, to facilitate lateral movement of a portion of the structuralbridge 522. Preferably, a biasing structure 560, communicating theattachment stay 548 (of FIG. 37), provides variable tension between thestructural bridge 522, and the second control module 504, therebyaccommodating a predetermined amount of lateral movement of thestructural bridge 522, relative to the bottom cover 550, as shown byFIG. 37.

As shown by FIG. 37, in a preferred embodiment, the attachment stay 548,includes at least, but not limited to, a guide aperture 562, which ispreferably slotted, interacting with the position guide 554, of theattachment boss 552 (of FIG. 38). The interaction of the guide aperture562, with the position guide 554, limits the extent of lateral alignmentbetween the structural bridge 522, and the control modules (502, 504).As further shown by FIG. 38, in a preferred embodiment, the attachmentsupport 556, further supports a plurality of control switches 564,interacting with a circuit structure 566, which preferably is a flexcircuit 566, and the biasing structure 560, is preferably a coiledspring 460.

In a preferred embodiment, the structural bridge 522, provides a width525, less than its length 527, as shown by FIG. 37, and the back of thecomputing device 506, extending above and below the width 525, of thestructural bridge 522.

Returning to FIG. 36, in a preferred embodiment, the input device 500,includes an auxiliary power source 529, and an auxiliary data storagedevice 531, which preferably includes a cache portion 533. Preferably,the auxiliary power source 529, is a lithium ion battery, which providespower to the input device 500, and the computing device 506, when thepower source of the computing device 506 is depilated; and the auxiliarydata storage device 531 is preferably a solid state hard drive.

FIG. 39 shows a further embodiment of the electronic gaming system 511,in which the input device 500, provides a keyboard module 535, and inwhich the keyboard module 535, passes signals to the computing device506, the signals control images displayed on the display screen 537, ofthe computing device 506.

FIG. 40 shows a still further embodiment of the electronic gaming system511, in which the input device 500, provides the keyboard module 535,and in which the keyboard module 535, passes signals to the computingdevice 506, the signals control images displayed on the display screen537, of the computing device 506. FIG. 40 further shows that thecommunication link 519, via the communication module 521, is furtherconfigured to communicate with a second display 541 wirelessly. That isthe second display 541, is remote from and mechanically disassociatedfrom the electronic display screen 537, of the computing device 506.

Continuing with FIG. 40, preferably each control module (502, 504)provides a directional control device 543. In a preferred embodiment,each direction control device 543, is configured to facilitate a firstposition adjacent the top cover 558, of control module 504, or a firstposition adjacent a top cover 545, of control module 502, and a secondposition, the second position displaced a predetermined verticaldistance away from the first position. Further in the preferredembodiment, each directional control module 543 is a joystick.

FIG. 41 discloses the electronic game control apparatus 400 (alsoreferred to herein as an input device 400), which in a preferredembodiment provides the first control module 402, the second controlmodule 404, and the structural bridge 422, which collectively securesthe computing device 418. In a preferred embodiment, a back of thestructural bridge 422, supports a touch sensitive control module 544,which in a preferred embodiment is a touch screen 544.

FIG. 42 discloses the electronic game control apparatus 400 (alsoreferred to herein as an input device 400), which in a preferredembodiment provides the first control module 402, the second controlmodule 404, and the structural bridge 422, which collectively securesthe computing device 418. In a preferred embodiment, a back 427, of thesecond control module 404, supports the touch sensitive control module544, which in a preferred embodiment is a touch screen 544.

It is to be understood that even though numerous characteristics andconfigurations of various embodiments of the present invention have beenset forth in the foregoing description, together with details of thestructure and function of various embodiments of the invention, thisdetailed description is illustrative only, and changes may be made indetail, especially in matters of structure and arrangements of partswithin the principles of the present invention to the full extentindicated by the broad general meaning of the terms in which theappended claims are expressed. For example, the particular elements mayvary depending on the particular computing device without departing fromthe spirit and scope of the present invention.

What is claimed is:
 1. A device comprising: a computing device, thecomputing device providing a plurality of sides, each of the pluralityof sides are disposed between an electronic display screen of thecomputing device and a back of the computing device, the computingdevice having a length greater than a width of the computing device; aninput device in electronic communication with the computing device, theinput device providing a pair of control modules, the pair of controlmodules adjacent to and confining the computing device on at least twoopposing sides of the plurality of sides of the computing device, thepair of control modules configured such that the pair of control modulesadaptively and snugly accommodate the width of the computing device,alternatively the pair of control modules adaptively and snuglyaccommodate a width of a second computing device, wherein the width ofthe second computing device is greater than the width of the computingdevice, and in which the second computing device having a length greaterthan the width of the computing device, wherein each of the pair ofcontrol modules provides a front side and a back side; a structuralbridge securing the pair of control modules one to the other, thestructural bridge in conjunction with the pair of control modulesforming a controller, the controller providing a front side and backside, the structural bridge configured such that the structural bridgeadaptively and snugly accommodates the length of the computing device,alternatively the structural bridge adaptively and snugly accommodatesthe length of the second computing device, wherein the length of thesecond computing device is greater than the length of the computingdevice, wherein the structural bridge provides a front side and a backside; and a touch sensitive input module attached to the back side ofthe controller.
 2. The device of claim 1, in which the touch sensitivemodule attached to the back side of the controller is attached to theback side of a selected control module of the pair of control modules,and in which the first of the pair of control modules comprising aretention mechanism communicating with the structural bridge, whereinthe retention mechanism secures the structural bridge such that thestructural bridge adaptively accommodates the length of the computingdevice, alternatively the structural bridge adaptively accommodates thelength of the second computing device, wherein the length of the secondcomputing device is greater than the length of the computing device. 3.The device of claim 1, in which the touch sensitive module attached tothe back side of the controller is attached to the back side of thestructural bridge, and in which a second of the pair of control modulescomprising a tensioning mechanism communicating with the structuralbridge, wherein the tensioning mechanism secures the structural bridgesuch that the structural bridge cooperating with the tensioningmechanism snugly accommodates the length of the computing device,alternatively the structural bridge cooperating with the tensioningmechanism snugly accommodates the length of the second computing device,wherein the length of the second computing device is greater than thelength of the computing device.
 4. The device of claim 1, in which eachof the pair of control modules comprising a sizing mechanismcommunicating with the computing device, wherein each of the sizingmechanisms is configured such that each sizing mechanism adaptivelyaccommodates the width of the computing device, alternatively eachsizing mechanism adaptively accommodates the width of the secondcomputing device, wherein the width of the second computing device isgreater than the width of the computing device.
 5. The device of claim2, in which the touch sensitive control module is a touch screen, and inwhich the first of the pair of control modules provides a base having anadjustment feature, and a top cover communicating with the base, and inwhich the retention mechanism comprises: a boss communicating with thestructural bridge; an adjustment structure interacting with the boss byway of the adjustment feature, the base disposed between the adjustmentstructure and the boss; and a restraint cooperating with the boss, therestraint retains the structural bridge in a first position relative tothe base when said adjustment structure is activated in a firstdirection relative to the base, the adjustment structure further retainsthe structural bridge in a second position relative to the base whensaid adjustment structure is activated in a second direction relative tothe base.
 6. The device of claim 5, in which the boss provides aconstraint feature cooperating with the base, the constraint featuremaintains the structural bridge in the first position relative to thebase following an activation of the adjustment structure in the firstdirection.
 7. The device of claim 6, in which the restraint is a springmember.
 8. The device of claim 7, wherein the second direction is adirection opposite that of the first direction.
 9. The device of claim3, in which the touch sensitive control module is a touch screen, and inwhich the second of the pair of control modules comprises a bottom coverand a top cover cooperating with the bottom cover, the bottom coverprovides a position guide, and in which the tensioning mechanismcomprises: an attachment boss communicating with the structural bridge;an attachment stay cooperating with the attachment boss, the attachmentstay in cooperation with the attachment boss confines the structuralbridge, the structural bridge disposed between the bottom cover and thetop cover; and a biasing structure communicating with the attachmentstay, the biasing structure provides variable tension between thestructural bridge and the second of the pair of control modules.
 10. Thedevice of claim 9, in which the attachment support comprises a guideaperture interacting with the position guide, the interaction of theguide aperture with the position guide maintains alignment between thestructural bridge and the second of the pair of control modules.
 11. Thedevice of claim 10, in which the guide aperture is a slotted aperture.12. The device of claim 11, in which the biasing structure is a coiledspring, and wherein cooperation between the top cover and the bottomcover facilitates movement of the structural bridge from a firstposition associated with a first position of an adjustment structurecooperating with the bottom cover, to a second position associated witha second position of the adjustment structure.
 13. The device of claim4, in which the first of the pair of control modules provides a basehaving a sizing toggle confinement structure and a slide supportconfinement structure, the sizing mechanism comprising: a sizing togglecommunicating with the sizing toggle confinement structure; a sizingtoggle restraint interacting with the sizing toggle confinementstructure, the sizing restraint promotes rotation of the sizing togglerelative to the base; and a torsional force structure cooperating withthe base and acting on the sizing toggle, the torsional force structurefacilitating the sizing toggle in a first position under a firsttorsional force, alternatively, the torsional force structurefacilitating the sizing toggle in a second position under a secondtorsional force, wherein the second torsional force is greater than thefirst torsional force.
 14. The device of claim 13, further comprising acomputing device slide pad nested in the slide support confinementstructure.
 15. The device of claim 14, in which the torsional forcestructure is a coiled spring.
 16. The device of claim 15, in which thesizing toggle confinement structure provides a friction surface, thefriction surface mitigates an inadvertent movement of the sizing togglefrom the first position to the second position when the computing deviceis constrained by the input device.
 17. The device of claim 2, in whichthe touch sensitive control module is a touch screen, and in which asecond of the pair of control modules comprising a tensioning mechanismcommunicating with the structural bridge, wherein the tensioningmechanism secures the structural bridge such that the structural bridgesnugly accommodates the length of the computing device, alternativelythe structural bridge snugly accommodates the length of the secondcomputing device, wherein the length of the second computing device isgreater than the length of the computing device.
 18. The device of claim17, in which each of the pair of control modules comprising a sizingmechanism communicating with the computing device, wherein each of thesizing mechanisms is configured such that each sizing mechanismadaptively accommodates the width of the computing device, alternativelyeach sizing mechanism adaptively accommodates the width of the secondcomputing device, wherein the width of the second computing device isgreater than the width of the computing device.
 19. The device of claim18, in which the first of the pair of control modules provides a basehaving an adjustment feature, and in which the retention mechanismcomprises: a boss communicating with the structural bridge; anadjustment structure interacting with the boss by way of the adjustmentfeature, the base disposed between the adjustment structure and theboss; and a restraint cooperating with the boss, the restraint retainsthe structural bridge in a first position relative to the base when saidadjustment structure is activated in a first direction relative to thebase, the adjustment structure further retains the structural bridge ina second position relative to the base when said adjustment structure isactivated in a second direction relative to the base.
 20. The device ofclaim 19, in which the boss provides a constraint feature cooperatingwith the base, the constraint feature maintains the structural bridge inthe first position relative to the base following an activation of theadjustment structure in the first direction.
 21. The device of claim 20,in which the restraint is a spring member.
 22. The device of claim 21,wherein the second direction is a direction opposite that of the firstdirection.
 23. The device of claim 22, in which the second of the pairof control modules comprises a bottom cover, the bottom cover provides aposition guide, and in which the tensioning mechanism comprises: anattachment boss communicating with the structural bridge; an attachmentsupport cooperating with the attachment boss, the attachment support incooperation with the attachment boss secures the structural bridge, thestructural bridge disposed between the attachment boss and theattachment support; and a biasing structure communicating with theattachment support, the biasing structure provides tension between thestructural bridge and the second of the pair of control modules.
 24. Thedevice of claim 23, in which the attachment support comprises a guideaperture interacting with the position guide, the interaction of theguide aperture with the position guide maintains alignment between thestructural bridge and the second of the pair of control modules.
 25. Thedevice of claim 24, in which the guide aperture is a slotted aperture.26. The device of claim 25, in which the biasing structure is a coiledspring.
 27. The device of claim 26, in which the first of the pair ofcontrol modules provides a base having a sizing toggle confinementstructure and a slide support confinement structure, the sizingmechanism comprising: a sizing toggle communicating with the sizingtoggle confinement structure; a sizing toggle restraint interacting withthe sizing toggle confinement structure, the sizing restraint promotesrotation of the sizing toggle relative to the base; and a torsionalforce structure cooperating with the base and acting on the sizingtoggle, the torsional force structure facilitating the sizing toggle ina first position under a first torsional force, alternatively, thetorsional force structure facilitating the sizing toggle in a secondposition under a second torsional force, wherein the second torsionalforce is greater than the first torsional force.
 28. The device of claim27, further comprising a computing device slide pad nested in the slidesupport confinement structure.
 29. The device of claim 28, in which thetorsional force structure is a coiled spring.
 30. The device of claim29, in which the sizing toggle confinement structure provides a frictionsurface, the friction surface mitigates an inadvertent movement of thesizing toggle from the first position to the second position when thecomputing device is constrained by the input device.